2. ( The World Health Organisation (1992) definition of
blindness is vision less than 3/60 in the better eye with best
available spectacle correction. )
Diabetes is therefore one of the most serious challenges to
health care world-wide. According to recent projections it will
affect 239 million people by 2010- doubling in prevalence
since 1994. Diabetes will affect 28 million in western Europe,
18.9 million in North America 138.2 million in Asia, 1.3
million in Australasia.
Diabetes mellitus is the most common cause of blindness
amongst individuals of working-age ( 20-65 years). The
prevalence of blindness due to DR in Western Communities is
estimated as between 1.6-1.9/ 100,000
3. About 2% of type 2 diabetics have CSME at
diagnosis and 10.2% have other signs of DR
already present when their diabetes is
discovered.
Mitchell and co- workers found that 15.8 %
of undiagnosed diabetics in an elderly
Australian population had signs of DR,
according to the recent Blue Mountains Eye
Study. Indeed it may often take from 9-12
years for type 2 diabetes to be diagnosed
4. Hyperglycaemia causes-
BM thickening
non enzymaitc glycosylation
increased free radical activity
increased flux through the polyol pathway
osmotic damage
Haemostatic abnormalities of the microcirculation-
It has also been postulated that platelet abnormalities in diabetics may
contribute to diabetic retinopathy. There are three steps in platelet
coagulation: initial adhesion, secretion, and further aggregation. It has been
shown that the platelets in diabetic patients are "stickier" than platelets of
non-diabetics They secrete prostaglandins that cause other platelets to
adhere to them (aggregation) and blockage of the vessel and endothelial
damage.
5.
6.
A useful classification according to the
types of lesions detected on
fundoscopy is as follows:
Non-proliferative diabetic retinopathy
(NPDR)
Mild non-proliferative diabetic retinopathy
Microaneurysms
Moderate NPDR
◦ Mild NPDR plus
◦ Dot and blot haemorrhages
◦ Hard ( intra-retinal ) exudates
7. Moderate-to-severe non-proliferative
diabetic retinopathy
The above lesions, usually with exacerbation,
plus:
1. Cotton-wool spots -4
2. Venous beading and loops-2
3. Intraretinal microvascular abnormalities ( IRMA )-1
8. Proliferative diabetic retinopathy
Neovascularization of the retina, optic disc or
iris
Fibrous tissue adherent to vitreous face of
retina
Retinal detachment
Vitreous haemorrhage
Pre retinal haemorrhage
10. Retinal microaneurysms are focal dilatations of retinal capillaries, 10
to 100 microns in diameter, and appear as red dots. They are
usually seen at the posterior pole, especially temporal to the fovea.
They may apparently disappear whilst new lesions appear at the
edge of areas of widening capillary non-perfusion. Microaneurysms
are the first ophthalmoscopically detectable change in diabetic
retinopathy.
Beginning as dilatations in areas in the capillary wall where pericytes
are absent, microaneurysms are initially thin-walled. Later,
endothelial cells proliferate and lay down layers of basement
membrane material around themselves.
Fibrin and erythrocytes may accumulate within the aneurysm.
Despite multiple layers of basement membrane, they are permeable
to water and large molecules, allowing the accumulation of water
and lipid in the retina. Since fluorescein passes easily through them,
many more microaneurysms are usually seen on fluorescein
angiography than are apparent on ophthalmoscopy
11. When the wall of a capillary or microaneurysm is sufficiently weakened, it
may rupture, giving rise to an intraretinal haemorrhage. If the hemorrhage is
deep (i.e., in the inner nuclear layer or outer plexiform layer), it usually is
round or oval ("dot or blot")
Dot haemorrhages appear as bright red dots and are the same size as large
microaneurysms. Blot haemorrhages are larger lesions they are located
within the mid retina and often within or surrounding areas of ischaemia.
(1,4,)
If the hemorrhage is more superficial and in the nerve fiber layer, it takes a
flame or splinter shape, which is indistinguishable from a hemorrhage seen in
hypertensive retinopathy. They often absorb slowly after several weeks. Their
presence strongly suggests the co-existence of systemic hypertension.
Diabetics with normal blood pressure may have multiple splinter
haemorrhages. Nevertheless, when an ophthalmologist sees numerous
splinter haemorrhages in a diabetic patient, the patient's blood pressure
must be checked because a frequent complication of diabetes is systemic
hypertension.
12.
13.
14. Cotton wool spots result from occlusion of
retinal pre-capillary arterioles supplying the
nerve fibre layer with concomitant swelling
of local nerve fibre axons. Also called "soft
exudates" or "nerve fibre layer infarctions"
they are white, fluffy lesions in the nerve
fibre layer. Fluorescein angiography shows
no capillary perfusion in the area of the soft
exudate. They are very common in DR,
especially if the patient is also hypertensive.
15.
16. Hard exudates ( Intra-retinal lipid exudates )
are yellow deposits of lipid and protein within
the sensory retina. Accumulations of lipids
leak from surrounding capillaries and
microaneuryisms, they may form a circinate
pattern. Hyperlipidaemia may correlate with
the development of hard exudates.
17. Accumulations of
lipids leak from
surrounding
capillaries and
microaneuryisms,
they may form a
circinate pattern.
18. Intra-retinal microvascular abnormalities ( IRMA)
are abnormal, dilated retinal capillaries or may
represent intraretinal neovacularization which
has not breached the internal limiting
membrane of the retina.
They indicate severe non-proliferative diabetic
retinopathy that may rapidly progress to
proliferative retinopathy.
Venous beading has an appearance resembling
sausage-shaped dilatation of the retinal veins.
It is another sign of severe non proliferative
diabetic retinopathy.
19.
20. Macular oedema is thus an important
manifestation of DR because it is now the
leading cause of legal blindness in
diabetics. The intercellular fluid comes from
leaking microaneurysms or from diffuse
capillary leakage .It should be stressed
however that current regimes now lay
emphasis on the treatment of retinal
thickening by grid laser than direct
treatment of microaneuyrisns and other
discreet lesions.
21. The leading cause of visual loss amongst diabetics. Diagnosed by stereoscopic
assessment of retinal thickening, usually by slit lamp biomicroscopy.
Defined as the presence of one or more of the following, ( Modified Airlie -House
Criteria )
Retinal oedema within 500 microns of the centre fovea.
Hard exudates within 500 microns of fovea if associated with adjacent retinal
thickening
Retinal oedema that is one disc diameter or larger, any part of which is within one
disc diameter of the centre of the fovea.
Laser grid photocoagulation reduces the risk of visual loss by 50% at 2 years
22.
23.
24. Maculopathy in type 1 diabetics is often due
to drop out of the perifoveal capillaries with
non perfusion and the consequent
development of an ischaemic maculopathy.
Enlargement of the foveal avascular zone
(FAZ) is frequently seen on fluorescein
angiography. Ischaemic maculopathy is not
uncommon in type 2 diabetics, maculopathy
in this group may show both changes due to
ischaemia but also retinal thickening.
25.
26.
Retinal ischaemia due to widespread capillary non perfusion results
in the production of vasoproliferative substances and to the
development of neovascularization. Neovascularization can involve
the retina, optic disc or the iris( rubeosis iridis).
Rubeosis iridis is a sign of severe proliferative disease, it may cause
intractable glaucoma.
Bleeding from fragile new vessels involving the retina or optic disc
can result in vitreous or retinal haemorrhage. Retinal damage can
result from persistent vitreous haemorrhage.
Pre-retinal haemorrhages are often associated with retinal
neovascularization, they may dramatically reduce vision within a
few minutes.
27.
28.
29.
30. Contraction of associated fibrous tissue
formed by proliferative disease tissue can
result in deformation of the retina and
tractional retinal detachment
31.
32. There are two types of diabetic retinal
detachments: those caused by traction alone
(nonrhegmatogenous) and those caused by
traction and retinal break formation
(rhegmatogenous)
Characteristics of nonrhegmatogenous
detachment in PDR include the following: (1)
the detached retina is usually confined to the
posterior fundus and infrequently extends
more than two thirds of the distance to the
equator; (2) it has a taut and shiny surface; (3)
it is concave toward the pupil; and (4) there is
no shifting of subretinal fluid.
33. The history of any visual symptoms or changes in vision
2. Measurement of visual acuity (unaided, with spectacles / pinhole
as necessary)
3. Iris examination by slit lamp biomicroscopy prior to pupil
mydriasis.
4. Pupil mydriasis. ( tropicamide 0.5 % ) -the risk of precipitating
angle closure glaucoma is actually very small. Patients should be
accompanied by a relative and instructed not to drive home.
5. Examination of the crystalline lens by slit lamp biomicroscopy.
6. Fundus examination by slit lamp biomicroscopy using diagnostic
contact lens or slit lamp indirect ophthalmoscopy.
34. It is now proven that good diabetic control may slow
the development and progression of diabetic
retinopathy in both type 1 and type 2 diabetes.
For example, the United Kingdom Prospective
Diabetes Study 1998 (UKPDS) followed 5,102 newly
diagnosed type 2 diabetics prospectively since 1977.
Those diabetics who were intensively treated and
achieved tight control with either insulin or
suphonylurea had diabetic endpoints 12% lower than
less well controlled diabetics.
Overall there was a 25% reduction in microvascular
end points in the group exhibiting good glycaemic
control.
35. Recent literature indicates that there is a
striking correlation between the presence of
systemic hypertension and progression of
diabetic retinopathy. Recent studies have
delineated the role of treating associated
hypertension and the slowing of the
progress of DR. It is important to note that
many type 2 diabetics will need a
combination of anti-hypertensive agents to
lower their blood pressure.
36.
37. The hypertension in diabetes study was launched within the original
UKPDS study in 1987.
The study compared diabetics whose blood pressure was tightly
controlled ( BP < 150/85)with ACE inhibitors and beta blockers with
a cohort whose blood pressure was less tightly controlled. (BP
<180/ 95 ) Median follow up was 8.4 years.
The reduction of macrovascular events was significant with a 32%
reduction in diabetes related deaths. There was a 44% reduction in
stroke and a 34% reduction in overall macrovascular disease.
UKPDS is a unique study in that it also looked at microvascular end
points in type 2 diabetics. Overall the tight control group had a 37%
reduction in microvascular disease, this was a more striking
reduction than tight glycaemic control.
This effect was manifested as a reduction of the risk of having to
undergo laser photocoagulation by 34%.
38. The risk of reduction of visual acuity was
lowered by 47%.
Atenolol and Captopril were equally
effective in reducing the risk of progression
of retinopathy in type 2 diabetics.
The Hypertension Optimal Treatment ( HOT
) study indicates that the lowest incidents of
cardiac events occurs when blood pressure
is lowered to 82.6 mmHg diastolic and 136
mmHg systolic.
39. The EUCLID study is currently investigating the
prophylactic treatment of type 1 diabetics with the
Angiotensin Converting Enzyme (ACE) Inhibitor
Lisinopril and the progression of nephropathy and
other microvascular disease including DR .
Preliminary reports are of a specific benefit are
encouraging, with a claimed 50% reduction in
progression of DR in type 1 diabetics.
The study did not look at maculopathy- so that
implications are unclear for type 2 diabetics,
although no specific advantage of ACE inhibitors
(Captopril) over Atenolol was seen in UKPDS.(31)
40. There is evidence in the literature that
diabetics who have exudative maculopathy
with extensive lipid exudes benefit from
active treatment of hyperlipidaemia
41. Diabetic nephropathy accelerates the
progression of retinopathy, especially
macular oedema, inter alia via increased
levels of fibrinogen and lipoprotein and
associated hypertension.
The visual prognosis is often better if the
nephropathy is treated by renal
transplantation rather than by dialysis
Any anaemia resulting from renal disease
must be aggressively treated.
Diabetic retinopathy is a common prelude to
the development of renal disease.
42. Pregnancy may accelerate the progression of diabetic retinopathy.
Frequency of monitoring NPDR should therefore be
increased.Women who begin a pregnancy with no retinopathy, the
risk of developing diabetic retinopathy is about 10%.
Those with DR at the onset of pregnancy may show progression,
with increased haemorrhages, soft exudates, and macular edema.
There is no doubt that women who maintain good metabolic control
during pregnancy have fewer spontaneous abortions and fewer
children with birth defects.
Those with untreated PDR at the onset frequently do poorly unless
they are treated with panretinal photocoagulation. Finally, patients
with previously treated PDR often do not worsen during the
pregnancy.
Women who begin pregnancy with poorly controlled diabetes and
who are suddenly brought under strict control frequently have
severe deterioration of their retinopathy and do not always recover
after delivery
43. Cataract surgery may lead to progression of
pre-existing macular oedema and
proliferative diabetic retinopathy. However,
cataracts may impede fundoscopy and
therefore interfere with the treatment of
diabetic retinopathy. If possible, diabetic
retinopathy should be treated prior to
cataract surgery
44. Tightening of glycaemic control may initially
produce worsening of retinopathy. The postulated
mechanism includes lowering of retinal blood low
or overproduction of IGF-1 by the liver.
It is therefore recommended that monitoring of
retinopathy is increased if major changes to
glycaemic control are made particularly in
previously poorly controlled diabetics. Ideally
glycated haemoglobin ( HbA1c) should be
maintained below 7%.
45. The mainstay of treatment of diabetic retinopathy is
retinal laser photocoagulation, an ablative treatment.
Laser therapy is highly effective; the rate of severe
visual loss at 2 years due to proliferative disease can
be reduced by 60%.
Laser photocoagulation causes a retinal burn which
is visible on fundoscopy. Retinal and optic disc
neovascularization can regress with the use of
retinal laser photocoagulation.
Rubeosis iridis requires urgent panretinal
photocoagulation to prevent ocular pain and
blindness from glaucoma.
46.
47.
48.
49. The indications for laser therapy now
include CSME which is treated with a
macular laser grid or treatment of focal
lesions such as microaneuryisms. Early
referral and detection of disease is
important as treatment of maculopathy is far
more successful if undertaken at an early
stage of the disease process.
There is a reduction in the rate of loss of
vision by 50% at 2 years with macular grid
therapy.
Pregnant patients should undergo laser
therapy if the usual indications are met.
50. The technique of laser photocoagulation
delivery involves the application of
eyedrops
( for pupil dilatation and corneal
anaesthesia ) and the application of an
optical contact lens. Mild proliferative
retinopathy is usually treated with at least
600 burns placed between the retinal
equator and the retinal vascular arcades. A
complete panretinal photocoagulation
treatment requires at least 1500 burns.
51. Although laser therapy can be highly effective in preventing blindness, it is
associated with numerous complications.
Retinal vein occlusion can follow inadvertent photocoagulation of a retinal
vein. Rarely, there may be loss of central acuity from inadvertent
photocoagulation of the fovea.
Vitreous haemorrhage can follow photocoagulation of retinal or choroidal
vessels.
There may be visual field restriction, decreased contrast sensitivity, impaired
night vision or impaired colour vision.
Visual field constriction may impair fitness to drive although
ophthalmologists increasingly strive to avoid this most undesirable problem,
for example by avoiding confluent laser burns.
A recent study indicates that 88% of diabetics who have undergone laser
photocoagulation would pass the Esterman binocular field test which is the
legal criterion for fitness to drive in the United Kingdom, even if both eyes
were treated. 42% of uniocular fields failed to make the criterion of a 120
degree horizontal field. Patients who have already lost the sight in one eye
therefore have a significant chance of failing to meet legal parameters for
fitness to drive in the United Kingdom.
Headache can sometimes follow laser therapy. The headache is usually
relieved with rest and simple analgesia. Glaucoma must be excluded if the
headache is severe or persistent.
52. Vitrectomy, plays a vital role in the
management of severe complications of
diabetic retinopathy.
The major indications are nonclearing
vitreous hemorrhage, traction retinal
detachment, and combined
traction/rhegmatogenous retinal
detachment. Less common indications are
macular edema with a thickened and taut
posterior hyaloid, macular heterotopia, and
tight preretinal macular hemorrhage.